Systems and methods to attenuate intermodulation interference

ABSTRACT

The present invention is directed to systems and method for attenuating intermodulation interference. In particular, methods and systems to attenuate intermodulation interference contained within an aggregate signal having a transmitted signal that was transmitted over a communications channel having channel effects that produce the intermodulation interference are provided. The communications channel may be a cable television distribution network and the signal may be a cable television signal. A method is provided to predict when intermodulation interference will be large, so that actions within a receiver can be taken to reduce the impact of the interference and improve overall receiver performance.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application claims priority to U.S. Provisional PatentApplication No. 60/685,528, entitled Systems and Methods to AttenuateIntermodulation Interference, filed on May 31, 2005 by Bruce J.Currivan, which is hereby expressly incorporated by reference in itsentirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to cable television distribution networks,and more specifically to canceling intermodulation products withincommunications signals transmitted on cable television distributionnetworks.

2. Background of Invention

A downstream cable TV plant typically carries tens to hundreds ofcarrier signals used to transmit television, Internet and other datainformation. These carriers are arranged in a frequency divisionmultiplexed (“FDM”) format with six megahertz (“Mhz”) spacing betweencarriers in North America and eight Mhz spacing in Europe.

A cable plant contains non-linear elements, such as amplifiers and laserdrivers that introduce intermodulation (“IM”) interference. When thecarrier signals pass through such non-linearities, intermodulationinterference is generated within the carrier signals. This interferenceis referred to as IM products. The IM products occur in frequencieswhich are the sum and difference of multiples of carrier frequencies andgenerally fall in the bands of the desired signals, where they interferewith the desired signals.

IM products are typically time varying within a signal envelope. The IMspectrum may contain a series of narrow lines, especially if the plantcontains many analog TV carriers such as in the case of a NationalTelevison System Committee (“NTSC”) formatted signal. The NTSC standardfor television defines a composite video signal with a refresh rate of60 half-frames (interlaced) per second. Each frame contains 525 linesand can contain 16 million different colors. The IM spectrum may bespread (i.e., not predominated by spectral lines) if the plant containsmostly digital carriers. Some of the digital carriers may bedata-bearing signals, such as Data Over Cable Service InterfaceSpecification (“DOCSIS”) signals. DOCSIS signals are used to supportcable modem data transmission. Second order IM products are referred toas composite second order (“CSO”) products and third order IM productsare referred to as composite triple beat (“CTB”) products.

Because the IM products interfere with a desired signal, methods toremove or attenuate the IM interference are needed. Typical approachesattempt to address this problem at the transmitter end of a cable plant.These approaches often assume the availability of original undistorteddata or knowledge of the nonlinearity. These systems are limited intheir ability to remove or attenuate IM interference because often areadily accessible version of the original undistorted signal and/orknowledge of the nonlinearity transfer characteristics are not wellknown.

What are needed are methods to reduce IM interference that do notrequire knowledge of the non-linearity and access to an originalundistorted signal.

BRIEF DESCRIPTION OF THE FIGURES

The invention is described with reference to the accompanying drawings.In the drawings, like reference numbers indicate identical orfunctionally similar elements. The drawing in which an element firstappears is indicated by the left-most digit in the correspondingreference number.

FIG. 1 is a diagram representing a signal transmitted through a model ofa non-linear cable television distribution plant.

FIG. 2 is a flow chart of an inverse method to attenuate intermodulationinterference.

FIG. 3 is a flow chart of a subtractive method to attenuateintermodulation interference.

FIG. 4 is a chart of the spectrum of a simulated transmitted signal.

FIG. 5 is a chart of the spectrum of a simulated transmitted signalhaving intermodulation interference.

FIG. 6 is a chart of the spectrum of a simulated transmitted signalhaving intermodulation interference in which the intermodulationinterference has been attenuated.

FIG. 7 is a diagram of an intermodulation interference attenuationsystem.

FIG. 8 is a flowchart of a method to predict intermodulationinterference and take corrective action.

DETAILED DESCRIPTION OF THE INVENTION

While the present invention is described herein with reference toillustrative embodiments for particular applications, it should beunderstood that the invention is not limited thereto. Those skilled inthe art with access to the teachings provided herein will recognizeadditional modifications, applications, and embodiments within the scopethereof and additional fields in which the invention would be ofsignificant utility.

This specification discloses one or more embodiments that incorporatethe features of this invention. The embodiment(s) described, andreferences in the specification to “one embodiment”, “an embodiment”,“an example embodiment”, etc., indicate that the embodiment(s) describedmay include a particular feature, structure, or characteristic, butevery embodiment may not necessarily include the particular feature,structure, or characteristic. Moreover, such phrases are not necessarilyreferring to the same embodiment. Further, when a particular feature,structure, or characteristic is described in connection with anembodiment, it is understood that it is within the knowledge of oneskilled in the art to effect such feature, structure, or characteristicin connection with other embodiments whether or not explicitlydescribed.

FIG. 1 is a diagram showing a signal transmitted through a model of anon-linear cable television distribution plant. Within a cabletelevision distribution plant, aggregate cable television signalsincluding multiple carriers, as represented by transmitted signal 150,are transmitted through cable television networks, as represented bynetwork 110, to provide an aggregate output signal, as represented bysignal 160.

Transmitted signal 150 includes frequencies that carry cable televisionchannel information, such as signal portions 152, 154, and 156. When acable signal, such as transmitted signal 150, passes through a cabletelevision network, the cable television network introducesintermodulation interference within a portion of the transmitted signal.The intermodulation interference interferes with desired signals andprevents efficient use of a portion of the spectrum.

Aggregate signal 160 illustrates transmitted signal 150 after it haspassed through cable television network 110. Aggregate signal 160includes the original signal portions 152, 154 and 156, but alsoincludes intermodulation interference signals 162, which are locatedwithin signal portion 156. The existence of intermodulation interferencesignals 162 will reduce the signal quality within signal portion 156 anddegrade overall system performance. As discussed above, the non-linearelements of a cable plant, such as amplifiers and laser driversintroduce intermodulation interference. When the carrier signals passthrough such non-linearities, intermodulation (“IM”) interference isgenerated within the carrier signals. This interference is referred toas IM products. The IM products occur in frequencies which are the sumand difference of multiples of carrier frequencies and generally fall inthe bands of the desired signals, where they interfere with the desiredsignals.

Cable television network 110 can be modeled as a series ofnon-linearities and filters, such as, for example, non-linearity 115,filter 120, non-linearity 125 and filter 130. The non-linearities can becaused by amplifiers and laser drivers. In this example, a transmittedsignal encounters the effects produced by non-linearity 115, then filter120, then non-linearity 125 and finally filter 130.

The methods to attenuate intermodulation interference disclosed belowtake advantage of the advent of modern analog-to-digital technology,which enables an aggregate signal to be available digitally in anintegrated circuit. Hence, all digital methods can be used to performthe cancellations needed. Furthermore, the methods focus on cancelingthe intermodulation products in a relatively narrow band of interest,nor over the entire band of the aggregate signal. This aids in simplifythe systems needed to attenuate or cancel the intermodulation products.For example, with DOCSIS and digital cable downstream signals, thesignal of interest may occupy a six MHz band, whereas the aggregatesignal occupies a band from 54 to 860 MHz, for a bandwidth of over 800MHz. Furthermore, other efficiencies can be gained in implementing themethods described below based on the application. For example, in acable distribution plant most discrete interference comes from theanalog TV channels, which occupy a band from 54 to around 550 MHz.Hence, efficiencies can be gained by processing the analog channelsonly, and saving processing bandwidth.

FIG. 2 provides a method 200 to attenuate intermodulation interferenceaccording to an embodiment of the invention. Method 200 attenuatesintermodulation interference contained within an aggregate signal of asignal that was transmitted over a communications channel having channeleffects that produce the intermodulation interference. Thecommunications channel may be a route within a cable television networkand the transmitted signal may be a cable television signal.

Method 200 begins in step 210. In step 210 an aggregate signal, such as,for example, aggregate signal 160 is received. As illustrated in FIG. 1,aggregate signal 160 will include a transmitted signal andintermodulation interference introduced by channel effects of the cabletelevision network. In step 220, the channel effects on the transmittedsignal are approximated. Thus, for example, the channel effectsrepresented by non-linearity 115, filter 120, non-linearity 125 andfilter 130 can be modeled. In step 230 the aggregate signal is passedthrough an inverse of the approximated channel effects to approximatelyremove or attenuate the intermodulation interference. Thus, for example,the received aggregate signal would be passed through an inverse ofnon-linearity 115, an inverse of filter 120, an inverse of non-linearity125 and an inverse of filter 130. Each inverse is only an approximation,since the channel effects are not assumed to be exactly known. Also,there will be some intermodulation interference produced between thedesired signal and other portions of the aggregate signal. Hence, someintermodulation interference can still exist within the signal after itis passed through the approximation of the inverse of the channeleffects. Method 200 ends in step 240.

The inversion described within method 200 can only be done practicallyif the channel components are all invertible. Gradual non-linearitiesare invertible. Sudden, severe non-linearities, such as clipping, arenot. Also, filters with deep nulls are not invertible in a practicalsense. Thus, method 200 has limitations with respect to itseffectiveness within existing cable networks, in which signals willoften encounter severe non-linearities.

FIG. 3 provides method 300 to cancel intermodulation interference. As inthe case of method 200, method 300 cancels intermodulation interferencecontained within an aggregate signal of a transmitted signal that wastransmitted over a communications channel having channel effects thatproduce the intermodulation interference. Method 300 includes additionalsteps to improve upon the attenuation of the intermodulationinterference signals. The communications channel may be a route within acable television network and the transmitted signal may be a cabletelevision signal.

Method 300 begins in step 310. In step 310 an aggregate signal, such as,for example, aggregate signal 160 is received. As illustrated in FIG. 1,aggregate signal 160 will include a transmitted signal andintermodulation interference introduced by channel effects of the cabletelevision network. In step 320, the aggregate signal is preserved. Instep 330 the aggregate signal is filtered to remove the desired signaland create an interference signal comprising the signals that producedthe intermodulation interference and the intermodulation interference.

In step 340, the channel effects on the transmitted signal areapproximated. Thus, for example, the channel effects represented bynon-linearity 115, filter 120, non-linearity 125 and filter 130 can bemodeled. In step 350 the interference signal is passed through anapproximation of the channel effects to create an approximation of theintermoduation interference. Thus, for example, the interference signalis passed through an approximation of non-linearity 115, filter 120,non-linearity 125 and filter 130. In step 360 the approximation of theintermodulation interference is subtracted from the aggregate signalthat was preserved in step 320 to produce an output signal in which theintermodulation interference has been attenuated from the receivedaggregate signal.

The following sequence of simulated spectrum plots illustrates theeffectiveness of method 300. FIG. 4 shows the spectrum of a transmittedsignal, such as transmitted signal 150. FIG. 4 plots frequency along thehorizontal axis and spectral density in dB along the vertical axis. FIG.4 shows that the transmitted signal includes multiple carriers atfrequencies ranging between 50 and 100 Mhz. To simulate the effects oftransmitting the signal through a cable television network, thetransmitted signal shown in FIG. 4 is passed through a 5^(th) order,memoryless nonlinearity with the transfer function:y=x+a ₂ x ² +a ₃ x ³ +a ₄ x ⁴ +a ₅ x ⁵wherea ₂=10⁻⁵a ₃=10⁻⁴a ₄=10⁻⁵a ₅=10⁻⁵

In this simplified example, no filtering is assumed to exist in thecable television network and only a single non-linearity exists. FIG. 5shows the aggregate signal, for example signal 160, that results frompassing the signal illustrated in FIG. 4 through a non-linear plant withthe transfer function assumed above. FIG. 5 plots frequency along thehorizontal axis and spectral density in dB along the vertical axis. FIG.5 shows that the aggregate signal includes multiple carriers atfrequencies ranging between 50 and 100 Mhz—the original transmittedsignal, but also shows the intermodulation interference that wasintroduced by the transfer function.

The signal illustrated in FIG. 5 is then passed through an approximationof the non-linearity channel effects to produce the estimatedintermodulation interference. The estimated intermodulation interferenceis then subtracted from the aggregate signal depicted in FIG. 5. In thissimplified example, the estimated non-linearity channel effects uses theexact coefficients (a₂ through a₅) of the plant non-linearity. In anactual system, the coefficients would be estimated using an adaptiveapproach. Approaches for estimating the coefficients include, but arenot limited to, a least mean square (LMS) method, a recursive leastsquares (RLS) method, and a minimum mean squared error (MMSE) method.

This process produces the signal illustrated in FIG. 6. The signalillustrated in FIG. 6 is equivalent to a signal produced through method300. FIG. 6 plots frequency along the horizontal axis and spectraldensity in dB along the vertical axis. FIG. 6 shows that the aggregatesignal includes multiple carriers at frequencies ranging between 50 and100 Mhz—the original transmitted signal, but also shows theintermodulation interference, which has been attenuated by approximately30 dB.

FIG. 7 shows an intermodulation interference attenuation system 700 toremove intermodulation interference. Intermodulation interferenceattenuation system 700 attenuates intermodulation interference within anaggregate signal containing a desired signal and intermodulationinterference that was transmitted over a communications channel havingchannel effects that produce the intermodulation interference. Inparticular, intermodulation interference attenuation system 700 can beused to implement method 300 described above. The communications channelmay be a cable television distribution network and the transmittedsignal may be a cable television signal.

Intermodulation interference attenuation system 700 includes a splitter710, a filter 720, a channel estimator 730, a channel approximator 740and an adder 750. Splitter 710 receives input signal 705, which is anaggregate signal. The aggregate signal includes a desired transmittedsignal (e.g., a cable television signal) and intermodulationinterference that was introduced by the communications channel. Anoutput of splitter 710 is coupled to filter 720 and an additional outputis coupled to adder 750. The output coupled to adder 750 serves topreserve the received aggregate signal for subsequent processing.

Filter 720 is coupled to splitter 710. Filter 720 removes the desiredsignal, such that all that remains are the adjacent signals.

Channel estimator 730 is coupled to filter 720. Channel estimator 730does not modify the output from filter 720. Rather, channel estimator730 uses the output to estimate a transfer function representing theimpacts of the communications channel. Channel estimator 730 can includea least mean square (LMS) estimation module, a recursive least squares(RLS) estimation module, or a minimum mean squared error (MMSE)estimation module to estimate coefficients for a transfer function. Inan alternative embodiment the original input signal containing thedesired signal can also be made available to channel estimator 730.Information obtained from the original signal can be used to increasethe accuracy of the channel estimation.

Channel approximator 740 is coupled to channel estimator 730. Channelapproximator 740 applies the transfer function estimated by channelestimator 730 to the signal produced by filter 720. Channel approximator740 produces a signal that approximately mimics intermodulationinterference introduced by the communications channel.

Adder 750 is coupled to the output of channel approximator 740 andsplitter 710. Adder 750 substracts the output of channel approximator740, which is an approximation of intermodulation interference producedby the communications channel from the aggregate signal which containsthe desired transmitted signal and intermodulation interference. Theresult is to produce an output signal in which intermodulationinterference has been attenuated and, therefore a truer representationof the original transmitted signal exists for further processing.

FIG. 8 provides method 800 for predicting that a strong intermodulationproduct will occur in the time domain. By knowing when a strongintermodulation product will occur, appropriate action can be taken tominimize the impact of the interference. Method 800 can be used inconjunction with methods 200 and 300 described above. Intermodulationinterference is time varying, since it consists of the sum of manyproducts which depend on an input signal, which is time varying. Whenthe intermodulation interference is large, this may be regarded as anoise impulse occurring in the band of interest. In this instance,symbol errors will then tend to occur when the signal of interest isdemodulated. Method 800 seeks to predict when the intermodulationinterference will be large and to take appropriate action to reduce thenumber of symbol errors.

Method 800 begins in step 810. In step 810 an aggregate signal, such assignal 160, is received. In step 820 a prediction is made whether theintermodulation interference will be large. The prediction can be basedon the nature of the transmitted signal and an estimation of the channeleffects, which can be determined as described above with respect tomethods 200 and 300. In step 830 a determination is made whether theintermodulation interference exceeds an acceptable threshold. If theintermodulation interference is beneath the acceptable threshold, method800 proceeds to step 870 and ends. If, however, the intermodulationinterference is above the acceptable threshold, method 800 proceeds tostep 840. In step 840 a tracking loop for symbol recovery is frozen. Instep 850 a determination is made whether the intermodulationinterference remains above the acceptable threshold. If theintermodulation interference remains above the acceptable threshold,method 800 returns to step 840 and the tracking loop remains frozen.This looping continues until the intermodulation interference dropsbelow the acceptable threshold. If the intermodulation interference hasdropped below the acceptable threshold, then method 800 proceeds to step860. In step 860 the tracking loop is unfrozen and the method proceedsto end in step 870.

Implementation of the above process can improve demodulation performancein a receiver. For example, if the phase tracking loop in a demodulatoris frozen before the intermodulation impulse occurs, then re-establishedafter the impulse subsides, the loop will not be subject to erroneousphase trajectory resulting from the impulse “hit,” and betterdemodulation performance will result.

In another embodiment, when the intermodulation interference ispredicted to be above an acceptable threshold, received symbols withinthe aggregate signal can be marked as erased or having a lower signal tonoise ratio. A front end processor can then give the marked symbolshigher performance by using this knowledge. For example, a Reed-Solomonfront end processor can correct twice as many erased bytes within amarked symbol as it can in errored bytes that were in an unmarked symbolto improve performance.

CONCLUSION

Exemplary embodiments of the present invention have been presented. Theinvention is not limited to these examples. These examples are presentedherein for purposes of illustration, and not limitation. Alternatives(including equivalents, extensions, variations, deviations, etc., ofthose described herein) will be apparent to persons skilled in therelevant art(s) based on the teachings contained herein. Suchalternatives fall within the scope and spirit of the invention.

What is claimed is:
 1. A method to attenuate intermodulationinterference contained within an aggregate signal having a desiredsignal that was transmitted over a communications channel with channeleffects that produce the intermodulation interference, comprising:receiving the aggregate signal, which contains the desired signal andthe intermodulation interference; preserving a copy of the aggregatesignal, which contains the desired signal and the intermodulationinterference; filtering the aggregate signal to remove the desiredsignal and create an interference signal comprising the intermodulationinterference and signals that produced the intermodulation interference;approximating the channel effects on the transmitted signal; passing theinterference signal through the approximated channel effects to producean approximation of the intermodulation interference; and subtractingthe approximation of the intermodulation interference from the preservedcopy of the aggregate signal, which contains the desired signal and theintermodulation interference.
 2. The method of claim 1, wherein thecommunications channel comprises a cable television distributionnetwork.
 3. The method of claim 1, wherein the desired signal comprisesa cable television signal.
 4. The method of claim 1, whereinapproximating the channel effects on the transmitted signal includesestimating coefficients for a non-linear transfer function thatrepresents the channel effects.
 5. The method of claim 4, whereinestimating coefficients includes using at least one of a least meansquare estimation, a recursive least squares estimation, and a minimummean squared error estimation.
 6. A system for attenuatingintermodulation interference contained within an aggregate signal havinga desired signal and intermodulation interference that was transmittedover a communications channel having channel effects that produce theintermodulation interference, comprising: a splitter configured toreceive and preserve a copy of the aggregate signal; a filter coupled tothe splitter configured to remove the desired signal from the aggregatesignal and to produce an adjacent signals signal; a channel estimatorcoupled to the filter configured to use the aggregate signal todetermine a transfer function that estimates impact on signalstransmitted over the communications channel; a channel approximatorcoupled to the channel estimator configured to apply the transferfunction estimated by the channel estimator to the adjacent signalssignal produced by the filter and to produce an approximateintermodulation interference mimic signal; and an adder coupled to thechannel approximator that subtracts the approximate intermodulationinterference mimic signal produced by the channel approximator from thecopy of the aggregate signal that was preserved by the splitter.
 7. Thesystem of claim 6, wherein the channel estimator includes at least oneof a least mean square estimation module, a recursive least squaresestimation module, and a minimum mean squared error estimation module.8. A method to predict when strong intermodulation interference willoccur in the time domain in a receiver, comprising: receiving anaggregate signal; predicting a magnitude of intermodulation interferencewithin the received aggregate signal by: estimating a transfer functionfor a communications channel upon which the received aggregate signalwas transmitted based on the received aggregate signal; and applyingthat transfer function to estimate intermodulation interference;determining if the magnitude of intermodulation interference exceeds anacceptable level; and taking an action to improve receiver performancewhen the magnitude of intermodulation interference exceeds an acceptablelevel.
 9. The method of claim 8, wherein estimating a transfer functioncomprises: using at least one of a least mean square estimation, arecursive least squares estimation, and a minimum mean squared errorestimation to estimate coefficients of the transfer function.
 10. Themethod of claim 8, wherein taking an action to improve receiverperformance comprises: freezing a phase tracking loop within ademodulator within the receiver.
 11. The method of claim 8, whereintaking an action to improve receiver performance comprises: markingreceived symbols within the received aggregate signal as erased whenintermodulation interference is predicted to exceed an acceptable level.12. The method of claim 8, wherein taking an action to improve receiverperformance comprises: marking received symbols within the receivedaggregate signal as having a lower signal to noise ratio whenintermodulation interference is predicted to exceed an acceptable level.